Event Recognition

ABSTRACT

A method executes software including a view hierarchy with a plurality of views which displays one or more views of the view hierarchy. The method executes software elements associated with a particular view, wherein each particular view includes event recognizers. Each event recognizer has an event definition based on sub-events, and an event handler that specifies an action for a target, and is configured to send the action to the target in response to an event recognition. The method detects a sequence of sub-events, and identifies one of the views of the view hierarchy as a hit view that establishes which views in the hierarchy are actively involved views. The method delivers a respective sub-event to event recognizers for each actively involved view, wherein each event recognizer for actively involved views in the view hierarchy processes the respective sub-event prior to processing a next sub-event in the sequence of sub-events.

RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 12/566,660, filed Sep. 24, 2009, entitled “Event Recognition,” which claims priority to U.S. Provisional Patent Application No. 61/210,332, “Event Recognition,” filed on Mar. 16, 2009, both of which are incorporated by reference herein in their entireties.

TECHNICAL FIELD

The disclosed embodiments relate generally to user interface processing. More particularly, the disclosed embodiments relate to apparatuses and methods for recognizing user interface events.

BACKGROUND

A computing device typically includes a user interface that may be used to interact with the computing device. The user interface may include a display and/or input devices such as a keyboard, mice, and touch-sensitive surfaces for interacting with various aspects of the user interface. In some devices with a touch-sensitive surface as an input device, a first set of touch-based gestures (e.g., two or more of: tap, double tap, horizontal swipe, vertical swipe, pinch, depinch, two finger swipe) are recognized as proper inputs in a particular context (e.g., in a particular mode of a first application), and other, different sets of touch-based gestures are recognized as proper inputs in other contexts (e.g., different applications and/or different modes or contexts within the first application). As a result, the software and logic required for recognizing and responding to touch-based gestures can become complex, and can require revision each time an application is updated or a new application is added to the computing device. These and similar issues may arise in user interfaces that utilize input sources other than touch-based gestures.

Thus, it would be desirable to have a comprehensive framework or mechanism for recognizing touch-based gestures and events, as well as gestures and events from other input sources, that is easily adaptable to virtually all contexts or modes of all application programs on a computing device, and that requires little or no revision when an application is updated or a new application is added to the computing device.

SUMMARY

To address the aforementioned drawbacks, some embodiments provide a method, which, at an electronic device configured to execute software that includes a view hierarchy with a plurality of views: displays one or more views of the view hierarchy; executes one or more software elements, each software element being associated with a particular view, wherein each particular view includes one or more event recognizers. Each event recognizer has an event definition based on one or more sub-events, and an event handler, wherein the event handler specifies an action for a target, and is configured to send the action to the target in response to the event recognizer detecting an event corresponding to the event definition. The method also detects a sequence of one or more sub-events, and identifies one of the views of the view hierarchy as a hit view, wherein the hit view establishes which views in the view hierarchy are actively involved views. The method also delivers a respective sub-event to event recognizers for each actively involved view within the view hierarchy, wherein each event recognizer for actively involved views in the view hierarchy processes the respective sub-event prior to processing a next sub-event in the sequence of sub-events.

Some embodiments provide a method, which, at an electronic device configured to execute software that includes a view hierarchy with a plurality of views: displays one or more views of the view hierarchy; executes one or more software elements, each software element being associated with a particular view, wherein each particular view includes one or more event recognizers. Each event recognizer has an event definition based on one or more sub-events, and an event handler, wherein the event handler specifies an action for a target, and is configured to send the action to the target in response to the event recognizer detecting an event corresponding to the event definition. The method also detects a sequence of one or more sub-events, and identifies one of the views of the view hierarchy as a hit view, wherein the hit view establishes which views in the view hierarchy are actively involved views. The method also delivers a respective sub-event to event recognizers for each actively involved view within the view hierarchy, and makes a sub-event recognition decision while processing the respective sub-event at event recognizers for the actively involved views in the view hierarchy.

Some embodiments provide a computer readable storage medium storing one or more programs for execution by one of more processors of a computer system or device, the one or more programs including one or more application programs for displaying one or more views of a view hierarchy with a plurality of views. The one or more application programs include one or more software elements, each software element being associated with a particular view, wherein each particular view includes one or more event recognizers. Each event recognizer has an event definition based on one or more sub-events, and an event handler, wherein the event handler: specifies an action for a target, and is configured to send the action to the target in response to the event recognizer detecting an event corresponding to the event definition; event management instructions, which when executed by the one or more processors of the computer system or device, cause the computer system or device to: detect a sequence of one or more sub-events; identify one of the views of the view hierarchy as a hit view, wherein the hit view establishes which views in the view hierarchy are actively involved views; and deliver a respective sub-event to event recognizers for each actively involved view within the view hierarchy, wherein each event recognizer for actively involved views in the view hierarchy processes the respective sub-event prior to processing a next sub-event in the sequence of sub-events.

Some embodiments provide an apparatus comprising a display, one or more processors, memory, and one or more programs stored in the memory, which are configured to display one or more views of a view hierarchy with a plurality of views. The one or more programs include one or more software elements, each software element being associated with a particular view, wherein each particular view includes one or more event recognizers. The event recognizers have an event definition based on one or more sub-events, and an event handler, wherein the event handler specifies an action for a target, and is configured to send the action to the target in response to the event recognizer detecting an event corresponding to the event definition. The apparatus's programs also include an event delivery program, which, when executed by the one or more processors of the apparatus, cause the apparatus to detect a sequence of one or more sub-events; identify one of the views of the view hierarchy as a hit view, wherein the hit view establishes which views in the view hierarchy are actively involved views; and make a sub-event recognition decision while event recognizers for the actively involved views in the view hierarchy process the respective sub-event.

In some embodiments, an apparatus is provided that comprises one or more processors, memory, and one or more programs stored in the memory, which are configured to manage execution of one or more programmatic layers of a programmatic hierarchy with a plurality of programmatic layers. The one or more programs include one or more software elements, each software element being associated with a particular programmatic layer, wherein each particular programmatic layer includes one or more event recognizers. The event recognizers have an event definition based on one or more sub-events, and an event handler, wherein the event handler specifies an action for a target and is configured to send the action to the target in response to the event recognizer detecting an event corresponding to the event definition. The apparatus also includes an event delivery program, which, when executed by the one or more processors of the apparatus, cause the apparatus to detect a sequence of one or more sub-events; identify one of the programmatic layers of the programmatic hierarchy as a hit layer, wherein the hit layer establishes which programmatic layers in the programmatic hierarchy are actively involved programmatic layers; and deliver a respective sub-event to event recognizers for each actively involved programmatic layer within the programmatic hierarchy, wherein each event recognizer for actively involved layers in the programmatic hierarchy processes the respective sub-event prior to processing a next sub-event in the sequence of sub-events.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A and 1B are block diagrams illustrating electronic devices, according to some embodiments.

FIG. 2 is a diagram of an input/output processing stack of an exemplary electronic device according to some embodiments.

FIG. 3A illustrates an exemplary view hierarchy, according to some embodiments.

FIGS. 3B and 3C are block diagrams illustrating exemplary event recognizer methods and data structures, according to some embodiments.

FIGS. 4A and 4B are flow charts illustrating exemplary state machines, according to some embodiments.

FIG. 4C illustrates the exemplary state machines of FIGS. 4A and 4B to an exemplary set of sub-events, according to some embodiments.

FIGS. 5A-5C illustrate exemplary sub-event sequences with exemplary event recognizer state machines, according to some embodiments.

FIGS. 6A and 6B are event recognition method flow diagrams, according to some embodiments.

Like reference numerals refer to corresponding parts throughout the drawings.

DESCRIPTION OF EMBODIMENTS

Reference will now be made in detail to embodiments, examples of which are illustrated in the accompanying drawings. In the following detailed description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. However, it will be apparent to one of ordinary skill in the art that the present invention may be practiced without these specific details. In other instances, well-known methods, procedures, components, circuits, and networks have not been described in detail so as not to unnecessarily obscure aspects of the embodiments.

It will also be understood that, although the terms first, second, etc. may be used herein to describe various elements, these elements should not be limited by these terms. These terms are only used to distinguish one element from another. For example, a first contact could be termed a second contact, and, similarly, a second contact could be termed a first contact, without departing from the scope of the present invention. The first contact and the second contact are both contacts, but they are not the same contact.

The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used in the description of the invention and the appended claims, the singular forms “a”, “an” and “the” are intended to include the plural forms as well, unless the context clearly indicates otherwise. It will also be understood that the term “and/or” as used herein refers to and encompasses any and all possible combinations of one or more of the associated listed items. It will be further understood that the terms “comprises” and/or “comprising,” when used in this specification, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof

As used herein, the term “if' may be construed to mean “when” or “upon” or “in response to determining” or “in response to detecting,” depending on the context. Similarly, the phrase “if it is determined” or “if [a stated condition or event] is detected” may be construed to mean “upon determining” or “in response to determining” or “upon detecting (the stated condition or event)” or “in response to detecting (the stated condition or event),” depending on the context.

As noted above, in some devices with a touch-sensitive surface as an input device, a first set of touch-based gestures (e.g., two or more of: tap, double tap, horizontal swipe, vertical swipe) are recognized as proper inputs in a particular context (e.g., in a particular mode of a first application), and other, different sets of touch-based gestures are recognized as proper inputs in other contexts (e.g., different applications and/or different modes or contexts within the first application). As a result, the software and logic required for recognizing and responding to touch-based gestures can become complex, and can require revision each time an application is updated or a new application is added to the computing device.

In the embodiments described below, touch-based gestures are events. Upon recognition of a predefined event, e.g., an event that corresponds to a proper input in the current context of an application, information concerning the event is delivered to the application. In the context of this document, all touch-based gestures correspond to events. Furthermore, each respective event is defined as a sequence of sub-events. In devices that have a multi-touch display device (often herein called “screens”) or other multi-touch sensitive surface, and that accept multi-touch-based gestures, the sub-events that define a multi-touched based event may include multi-touch sub-events (requiring two or more fingers to be simultaneously in contact with the device's touch-sensitive surface). For example, in a device having a multi-touch sensitive display, a respective multi-touch sequence of sub-events may begin when a user's finger first touches the screen. Additional sub-events may occur when one or more additional fingers subsequently or concurrently touch the screen, and yet other sub-events may occur when all of the fingers touching the screen move across the screen. The sequence ends when the last of the user's fingers is lifted from the screen.

When using touch-based gestures to control an application running in a device having a touch-sensitive surface, touches have both temporal and spatial aspects. The temporal aspect, called a phase, indicates when a touch has just begun, whether it is moving or stationary, and when it ends—that is, when the finger is lifted from the screen. A spatial aspect of a touch is the set of views or user interface windows in which the touch occurs. The views or windows in which a touch is detected may correspond to programmatic levels within a programmatic or view hierarchy. For example, the lowest level view in which a touch is detected may be called the hit view, and the set of events that are recognized as proper inputs may be determined based, at least in part, on the hit view of the initial touch that begins a touch-based gesture.

FIGS. 1A and 1B are block diagrams illustrating electronic devices 102 and 104, according to some embodiments. The electronic devices 102 and 104 may be any electronic device including, but not limited to, a desktop computer system, a laptop computer system, mobile phone, a smart phone, a personal digital assistant, or a navigation system. The electronic device may also be a portable electronic device with a touch screen display (e.g., display 156, FIG. 1B) configured to present a user interface, a computer with a touch screen display configured to present a user interface, a computer with a touch sensitive surface and a display configured to present a user interface, or any other form of computing device, including without limitation, consumer electronic devices, mobile telephones, video game systems, electronic music players, tablet PCs, electronic book reading systems, e-books, PDAs, electronic organizers, email devices, laptops or other computers, kiosk computers, vending machines, smart appliances, etc. The electronic devices 102 and 104 may include user interfaces 113-A and 113-B, respectively.

In some embodiments, the electronic devices 102 and 104 include a touch screen display. In these embodiments, the user interface 113 (i.e., 113-A or 113-B) may include an on-screen keyboard (not depicted) that is used by a user to interact with the electronic devices 102 and 104. Alternatively, a keyboard may be separate and distinct from the electronic devices 102 and 104. For example, a keyboard may be a wired or wireless keyboard coupled to the electronic devices 102 or 104.

In some embodiments, the electronic device 102 includes a display 126 and one or more input devices 128-A (e.g., keyboard, mouse, trackball, microphone, physical button(s), touchpad, etc.) that are coupled to the electronic device 102. In these embodiments, one or more of the input devices 128-A may optionally be separate and distinct from the electronic device 102. For example, the one or more input devices may include one or more of: a keyboard, a mouse, a trackpad, a trackball, and an electronic pen, any of which may optionally be separate from the electronic device. Optionally, the device 102 or 104 may include one or more sensors 130, such as one or more accelerometers, gyroscopes, GPS systems, speakers, infrared (IR) sensors, biometric sensors, cameras, etc. It is noted that the description above of various exemplary devices as input devices 128 or as sensors 130 is of no significance to the operation of the embodiments described herein, and that any input or sensor device herein described as an input device may equally well be described as a sensor, and vice versa. In some embodiments, signals produced by the one or more sensors 130 are used as input sources for detecting events.

In some embodiments, the electronic device 104 includes a touch-sensitive display 156 (i.e., a display having a touch-sensitive surface) and one or more input devices 128-B that are coupled to the electronic device 104. In some embodiments, the touch-sensitive display 156 has the ability to detect two or more distinct, concurrent (or partially concurrent) touches, and in these embodiments, the display 156 is sometimes herein called a multitouch display or multitouch-sensitive display.

In some embodiments of the electronic device 102 or 104 discussed herein, the input devices 128 are disposed in the electronic device 102 or 104. In other embodiments, one or more of the input devices 128 is separate and distinct from the electronic device 102 or 104; for example, one or more of the input devices 128 may be coupled to the electronic device 102 or 104 by a cable (e.g., USB cable) or wireless connection (e.g., Bluetooth connection).

When using the input devices 128, or when performing a touch-based gesture on the touch-sensitive display 156 of an electronic device 102 or 104, respectively, the user generates a sequence of sub-events that are processed by one or more CPUs 110 of the electronic device 102 or 104. In some embodiments, the one or more CPUs 110 of the electronic device 102 or 104 process the sequence of sub-events to recognize events.

The electronic device 102 or 104 typically includes one or more single- or multi-core processing units (“CPU” or “CPUs”) 110 as well as one or more network or other communications interfaces 112, respectively. The electronic device 102 or 104 includes memory 111 and one or more communication buses 115, respectively, for interconnecting these components. The communication buses 115 may include circuitry (sometimes called a chipset) that interconnects and controls communications between system components (not depicted herein). As discussed briefly above, the electronic devices 102 and 104 optionally include user interfaces 113 that include a display 126 and multitouch display 156, respectively. Further, the electronic devices 102 and 104 typically include input devices 128 (e.g., keyboard, mouse, touch screens, touch sensitive surfaces, multitouch screens, keypads, etc.). In some embodiments, the input devices include an on-screen input device (e.g., a touch-sensitive surface of a display device). Memory 111 may include high-speed random access memory, such as DRAM, SRAM, DDR RAM or other random access solid state memory devices; and may include non-volatile memory, such as one or more magnetic disk storage devices, optical disk storage devices, flash memory devices, or other non-volatile solid state storage devices. Memory 111 may optionally include one or more storage devices remotely located from the CPU(s) 110. Memory 111, or alternately the non-volatile memory device(s) within memory 111, comprise a computer readable storage medium. In some embodiments, memory 111 stores the following programs, modules and data structures, or a subset thereof:

-   -   an operating system 118 that includes procedures for handling         various basic system services and for performing hardware         dependent tasks;     -   a communication module 120 (in electronic devices 102 and 104,         respectively) that is used for connecting the electronic device         102 or 104, respectively, to other devices via their one or more         respective communication interfaces 112 (wired or wireless) and         one or more communication networks, such as the Internet, other         wide area networks, local area networks, metropolitan area         networks, and so on;     -   an event delivery system 122 (in electronic devices 102 and 104,         respectively) that may be implemented in various alternate         embodiments within the operating system 118 or in application         software 124; in some embodiments, however, some aspects of         event delivery system 122 may be implemented in the operating         system 118 while other aspects are implemented in application         software 124; and     -   one or more applications in application software 124,         respectively (e.g., an email application, a web browser         application, a text messaging application, etc.).

Each of the above identified elements may be stored in one or more of the previously mentioned memory devices, and corresponds to a set of instructions for performing functions described herein. The set of instructions can be executed by one or more processors (e.g., the one or more CPUs 110). The above identified modules or programs (i.e., sets of instructions) need not be implemented as separate software programs, procedures or modules, and thus various subsets of these modules may be combined or otherwise rearranged in various embodiments. In some embodiments, memory 111 may store a subset of the modules and data structures identified above. Furthermore, memory 111 may store additional modules and data structures not described above.

FIG. 2 is a diagram of an input/output processing stack 200 of an exemplary electronic device or apparatus (e.g., device 102 or 104) according to some embodiments of the invention. The hardware (e.g., electronic circuitry) 212 of the device is at the base level of the input/output processing stack 200. Hardware 212 can include various hardware interface components, such as the components depicted in FIGS. 1A and/or 1B. Hardware 212 can also include one or more of the above mentioned sensors 130. All the other elements (202-210) of the input/output processing stack 200 are software procedures, or portions of software procedures, that process inputs received from the hardware 212 and generate various outputs that are presented through a hardware user interface (e.g., one or more of a display, speakers, device vibration actuator).

A driver or a set of drivers 210 communicates with the hardware 212. The drivers 210 can receive and process input data received from the hardware 212. A core Operating System (“OS”) 208 can communicate with the driver(s) 210. The core OS 208 can process raw input data received from the driver(s) 210. In some embodiments, the drivers 210 can be considered to be a part of the core OS 208.

A set of OS application programming interfaces (“OS APIs”) 206, are software procedures that communicate with the core OS 208. In some embodiments, the APIs 206 are included in the device's operating system, but at a level above the core OS 208. The APIs 206 are designed for use by applications running on the electronic devices or apparatuses discussed herein. User interface (UI) APIs 204 can utilize the OS APIs 206. Application software (“applications”) 202 running on the device can utilize the UI APIs 204 in order to communicate with the user. The UI APIs 204 can, in turn, communicate with lower level elements, ultimately communicating with various user interface hardware, e.g., multitouch display 156.

While each layer input/output processing stack 200 can utilize the layer underneath it, that is not always required. For example, in some embodiments, applications 202 can occasionally communicate with OS APIs 206. In general, layers at or above the OS API layer 206 may not directly access the Core OS 208, driver(s) 210, or hardware 212, as these layers are considered private. Applications in layer 202 and the UI API 204 usually direct calls to the OS API 206, which in turn, accesses the layers Core OS 208, driver(s) 210, and hardware 212.

Stated in another way, one or more hardware elements 212 of the electronic device 102 or 104, and software running on the device, such as, for example, drivers 210 (depicted in FIG. 2), core OS (operating system) 208 (depicted in FIG. 2), operating system API software 206 (depicted in FIG. 2), and Application and User Interface API software 204 (depicted in FIG. 2) detect input events (which may correspond to sub-events in a gesture) at one or more of the input device(s) 128 and/or a touch-sensitive display 156 and generate or update various data structures (stored in memory of the device 102 or 104) used by a set of currently active event recognizers to determine whether and when the input events correspond to an event to be delivered to an application 202. Embodiments of event recognition methodologies, apparatus and computer program products are described in more detail below.

FIG. 3A depicts an exemplary view hierarchy 300, which in this example is a search program displayed in outermost view 302. Outermost view 302 generally encompasses the entire user interface a user may directly interact with, and includes subordinate views, e.g.,

-   -   search results panel 304, which groups search results and can be         scrolled vertically;     -   search field 306, which accepts text inputs; and     -   a home row 310, which groups applications for quick access.

In this example, each subordinate view includes lower-level subordinate views. In other examples, the number of view levels in the hierarchy 300 may differ in different branches of the hierarchy, with one or more subordinate views having lower-level subordinate views, and one or more other subordinate views not have any such lower-level subordinate views. Continuing with the example shown in FIG. 3A, search results panel 304 contains separate subordinate views 305 (subordinate to the panel 304) for each search result. Here, this example shows one search result in a subordinate view called the maps view 305. Search field 306 includes a subordinate view herein called the clear contents icon view 307, which clears the contents of the search field when a user performs a particular action (e.g., a single touch or tap gesture) on the clear contents icon in the view 307. Home row 310 includes subordinate views 310-1, 310-2, 310-3, and 310-4, which respectively correspond to a contacts application, an email application, a web browser, and an iPod music interface.

A touch sub-event 301-1 is represented in outermost view 302. Given the location of touch sub-event 301-1 over both the search results panel 304, and maps view 305, the touch sub-event is also represented over those views as 301-2 and 301-3, respectively. Actively involved views of the touch sub-event include the views search results panel 304, maps view 305 and outermost view 302. Additional information regarding sub-event delivery and actively involved views is provided below with reference to FIGS. 3B and 3C.

Views (and corresponding programmatic levels) can be nested. In other words, a view can include other views. Consequently, the software element(s) (e.g., event recognizers) associated with a first view can include or be linked to one or more software elements associated with views within the first view. While some views can be associated with applications, others can be associated with high level OS elements, such as graphical user interfaces, window managers, etc.

To simplify subsequent discussion, reference will generally be made only to views and the view hierarchy, but it must be understood that in some embodiments, the method may operate with a programmatic hierarchy with a plurality of programmatic layers, and/or a view hierarchy.

FIGS. 3B and 3C depict exemplary methods and structures related to event recognizers. FIG. 3B depicts methods and data structures for event handling when event handlers are associated with particular views within a hierarchy of views. FIG. 3C depicts methods and data structures for event handling when event handlers are associated with particular levels within a hierarchy of programmatic levels. Event recognizer global methods 312 and 350 include hit view and hit level determination modules 314 and 352, respectively, active event recognizer determination modules 316 and 354, and sub-event delivery modules 318 and 356.

Hit view and hit level determination modules, 314 and 352, respectively, provide software procedures for determining where a sub-event has taken place within one or more views, e.g., the exemplary view hierarchy 300 depicted in FIG. 3A, which has three main branches.

The hit view determination module 314 of FIG. 3B, receives information related to a sub-event, e.g., a user touch represented as 301-1 on the outermost view 302, on a search result (map view 305) and the search results panel view 304. The hit view determination module 314 identifies a hit-view as the lowest view in the hierarchy which should handle the sub-event. In most circumstances, the hit view is the lowest level view in which an initiating sub-event (i.e., the first sub-event in the sequence of sub-events that form an event or potential event) occurs. Once the hit-view is identified, it will receive all sub-events related to the same touch or input source for which the hit view was identified.

In some embodiments, the hit level determination module 352 of FIG. 3C may utilize an analogous process.

Active event recognizer determination modules 316 and 354 of event recognizer global methods 312 and 350, respectively, determine which view or views within a view hierarchy should receive a particular sequence of sub-events. FIG. 3A depicts an exemplary set of active views, 302, 304 and 305, that receive the sub-event 301. In the example of FIG. 3A, the active event recognizer determination module 304 would determine that the top level view 302, search results panel 304 and maps view 305 are actively involved views because these views include the physical location of the touch represented by sub-event 301. It is noted that even if touch sub-event 301 were entirely confined to the area associated with map view 305, search results panel 304 and top level view 302 would still remain in the actively involved views since the search results panel 304 and the top level view 302 are ancestors of map view 305.

In some embodiments, active event recognizer determination modules 316 and 354 utilize analogous processes.

Sub-event delivery module 318 delivers sub-events to event recognizers for actively involved views. Using the example of FIG. 3A, a user's touch is represented in different views of the hierarchy by touch marks 301-1, 301-2, and 301-3. In some embodiments, sub-event data representing this user's touch is delivered by the sub-event delivery module 318 to event recognizers at the actively involved views, i.e., top level view 302, search results panel 304 and maps view 305. Further, the event recognizers of a view can receive subsequent sub-events of an event that starts within the view (e.g., when an initial sub-event occurs within the view). Stated in another way, a view can receive sub-events associated with user interactions beginning in the view, even if it continues outside of the view.

In some embodiments, sub-event delivery module 356 delivers sub-events to event recognizers for actively involved programmatic levels in a process analogous to that used by sub-event delivery module 318.

In some embodiments, a separate event recognizer structure 320 or 360 is generated and stored in memory of the device for each actively involved event recognizer Event recognizer structures 320 and 360 typically include an event recognizer state 334, 374, respectively (discussed in greater detail below when referring to FIGS. 4A and 4B), and event recognizer specific code 338, 378, respectively, having state machines 340, 380, respectively. Event recognizer structure 320 also includes a view hierarchy reference 336, while event recognizer structure 360 includes a programmatic hierarchy reference 376. Each instance of a particular event recognizer references exactly one view or programmatic level. View hierarchy reference 336 or programmatic hierarchy reference 376 (for a particular event recognizer) are used to establish which view or programmatic level is logically coupled to the respective event recognizer.

View metadata 341 and level metadata 381 may include data regarding a view or level, respectively. View or level metadata may include at least the following properties that may influence sub-event delivery to event recognizers:

-   -   A stop property 342, 382, which, when set for a view or         programmatic level prevents sub-event delivery to event         recognizers associated with the view or programmatic level as         well as its ancestors in the view or programmatic hierarchy.     -   A skip property 343, 383, which, when set for a view or         programmatic level prevents sub-event delivery to event         recognizers associated with that view or programmatic level, but         permits sub-event delivery to its ancestors in the view or         programmatic hierarchy.     -   A NoHit skip property 344, 384, which, when set for a view,         prevents delivery of sub-events to event recognizers associated         with the view unless the view is the hit view. As discussed         above, the hit view determination module 314 identifies a         hit-view (or hit-level in the case of hit-level determination         module 352) as the lowest view in the hierarchy which should         handle the sub-event.

Event recognizer structures 320 and 360 may include metadata 322, 362, respectively. In some embodiments, the metadata 322, 362 includes configurable properties, flags, and lists that indicate how the event delivery system should perform sub-event delivery to actively involved event recognizers. In some embodiments, metadata 322, 362 may include configurable properties, flags, and lists that indicate how event recognizers may interact with one another. In some embodiments, metadata 322, 362 may include configurable properties, flags, and lists that indicate whether sub-events are delivered to varying levels in the view or programmatic hierarchy. In some embodiments, the combination of event recognizer metadata 322, 362 and view or level metadata (341, 381, respectively) are both be used to configure the event delivery system to: a) perform sub-event delivery to actively involved event recognizers, b) indicate how event recognizers may interact with one another, and c) indicate whether and when sub-events are delivered to various levels in the view or programmatic hierarchy.

It is noted that, in some embodiments, a respective event recognizer sends an event recognition action 333, 373 to its respective target 335, 375, as specified by fields of the event recognizer's structure 320, 360. Sending an action to a target is distinct from sending (and deferred sending) sub-events to a respective hit view or level.

The metadata properties stored in a respective event recognizer structure 320, 360 of a corresponding event recognizer includes at least:

-   -   An exclusivity flag 324, 364, which, when set for an event         recognizer, indicates that upon recognition of an event by the         event recognizer, the event delivery system should stop         delivering sub-events to any other event recognizers of the         actively involved views or programmatic levels (with the         exception of any other event recognizers listed in an exception         list 326, 366). When receipt of a sub-event causes a particular         event recognizer to enter the exclusive state, as indicated by         its corresponding exclusivity flag 324 or 364, then subsequent         sub-events are delivered only to the event recognizer in the         exclusive state (as well as any other event recognizers listed         in an exception list 326, 366).     -   Some event recognizer structures 320, 360, may include an         exclusivity exception list 326, 366. When included in the event         recognizer structure 320, 360 for a respective event recognizer,         this list 326, 366 indicates the set of event recognizers, if         any, that are to continue receiving sub-events even after the         respective event recognizer has entered the exclusive state. For         example, if the event recognizer for a single tap event enters         the exclusive state, and the currently involved views include an         event recognizer for a double tap event, then the list 320, 360         would list the double tap event recognizer so that a double tap         event can be recognized even after a single tap event has been         detected. Accordingly, the exclusivity exception list 326, 366         permits event recognizers to recognize different events that         share common sequences of sub-events, e.g., a single tap event         recognition does not preclude subsequent recognition of a double         or triple tap event by other event recognizers.     -   Some event recognizer structures 320, 360, may include a         wait-for list 327, 367. When included in the event recognizer         structure 320, 360 for a respective event recognizer, this list         327, 367 indicates the set of event recognizers, if any, that         must enter the event impossible or event canceled state before         the respective event recognizer can recognize a respective         event. In effect, the listed event recognizers have higher         priority for recognizing an event than the event recognizer with         the wait-for list 327, 367.     -   A delay touch began flag 328, 368, which, when set for an event         recognizer, causes the event recognizer to delay sending         sub-events (including a touch begin or finger down sub-event,         and subsequent events) to the event recognizer's respective hit         view or level until after it has been determined that the         sequence of sub-events does not correspond to this event         recognizer's event type. This flag can be used to prevent the         hit view or level from ever seeing any of the sub-events in the         case where the gesture is recognized. When the event recognizer         fails to recognize an event, the touch began sub-event (and         sub-sequent touch end sub-event) can be delivered to the hit         view or level. In one example, delivering such sub-events to the         hit view or level causes the user interface to briefly highlight         an object, without invoking the action associated with that         object.     -   A delay touch end flag 330, 370, which, when set for an event         recognizer, causes the event recognizer to delay sending a         sub-event (e.g., a touch end sub-event) to the event         recognizer's respective hit view or level until it has been         determined that the sequence of sub-events does not correspond         to this event recognizer's event type. This can be used to         prevent the hit view or level from acting upon a touch end         sub-event, in case the gesture is late recognized. As long as         the touch end sub-event is not sent, a touch canceled can be         sent to the hit view or level. If an event is recognized, the         corresponding action by an application is preformed, and the         touch end sub-event is delivered to the hit view or level.     -   A touch cancellation flag 332, 372, which, when set for an event         recognizer, causes the event recognizer to send touch or input         cancellation to the event recognizer's respective hit view or         hit level when it has been determined that the sequence of         sub-events does not correspond to this event recognizer's event         type. The touch or input cancellation sent to the hit view or         level indicates that a prior sub-event (e.g., a touch began         sub-event) has been cancelled. The touch or input cancellation         may cause the input source handler's state (see FIG. 4B) to         enter the input sequence cancelled state 460 (discussed below).

In some embodiments, the exception list 326, 366 can also be used by non-exclusive event recognizers. In particular, when a non-exclusive event recognizer recognizes an event, subsequent sub-events are not delivered to the exclusive event recognizers associated with the currently active views, except for those exclusive event recognizers listed in the exception list 326, 366 of the event recognizer that recognized the event.

In some embodiments, event recognizers may be configured to utilize the touch cancellation flag in conjunction with the delay touch end flag to prevent unwanted sub-events from being delivered to the hit view. For example, the definition of a single tap gesture and the first half of a double tap gesture are identical. Once a single tap event recognizer successfully recognizes a single tap, an undesired action could take place. If the delay touch end flag is set, the single tap event recognizer is prevented from sending sub-events to the hit view until a single tap event is recognized. In addition, the wait-for list of the single tap event recognizer may identify the double-tap event recognizer, thereby preventing the single tap event recognizer from recognizing a single tap until the double-tap event recognizer has entered the event impossible state. The use of the wait-for list avoids the execution of actions associated with a single tap when a double tap gesture is performed. Instead, only actions associated with a double tap will be executed, in response to recognition of the double tap event.

Turning in particular to forms of user touches on touch-sensitive surfaces, as noted above, touches and user gestures may include an act that need not be instantaneous, e.g., a touch can include an act of moving or holding a finger against a display for a period of time. A touch data structure, however, defines the state of a touch (or, more generally, the state of any input source) at a particular time. Therefore, the values stored in a touch data structure may change over the course of a single touch, enabling the state of the single touch at different points in time to be conveyed to an application.

Each touch data structure can comprise various fields. In some embodiments, touch data structures may include data corresponding to at least the touch-specific fields 339 in FIG. 3B or input source specific fields 379 in FIG. 3C.

For example, a “first touch for view” field 345 in FIG. 3B (385 for “first touch for level” in FIG. 3C) can indicate whether the touch data structure defines the first touch for the particular view (since the software element implementing the view was instantiated). A “time stamp” field 346, 386 can indicate the particular time to which the touch data structure relates.

Optionally, an “info” field 347, 387 can be used to indicate if a touch is a rudimentary gesture. For example, the “info” field 347, 387 can indicate whether the touch is a swipe and, if so, in which direction the swipe is oriented. A swipe is a quick drag of one or more fingers in a straight direction. API implementations (discussed below) can determine if a touch is a swipe and pass that information to the application through the “info” field 347, 387, thus alleviating the application of some data processing that would have been necessary if the touch were a swipe.

Optionally, a “tap count” field 348 in FIG. 3B (“event count” field 388 in FIG. 3C) can indicate how many taps have been sequentially performed at the position of the initial touch. A tap can be defined as a quick pressing and lifting of a finger against a touch-sensitive panel at a particular position. Multiple sequential taps can occur if the finger is again pressed and released in quick succession at the same position of the panel. An event delivery system 124 can count taps and relay this information to an application through the “tap count” field 348. Multiple taps at the same location are sometimes considered to be a useful and easy to remember command for touch enabled interfaces. Thus, by counting taps, the event delivery system 124 can again alleviate some data processing from the application.

A “phase” field 349, 389 can indicate a particular phase the touch-based gesture is currently in. The phase field 349, 389 can have various values, such as “touch phase began” which can indicate that the touch data structure defines a new touch that has not been referenced by previous touch data structures. A “touch phase moved” value can indicate that the touch being defined has moved from a prior position. A “touch phase stationary” value can indicate that the touch has stayed in the same position. A “touch phase ended” value can indicate that the touch has ended (e.g., the user has lifted his/her finger from the surface of a multi touch display). A “touch phase cancelled” value can indicate that the touch has been cancelled by the device. A cancelled touch can be a touch that is not necessarily ended by a user, but which the device has determined to ignore. For example, the device can determine that the touch is being generated inadvertently (i.e., as a result of placing a portable multi touch enabled device in one's pocket) and ignore the touch for that reason. Each value of the “phase field” 349, 389 can be a integer number.

Thus, each touch data structure can define what is happening with a touch (or other input source) at a particular time (e.g., whether the touch is stationary, being moved, etc.) as well as other information associated with the touch (such as position). Accordingly, each touch data structure can define the state of a particular touch at a particular moment in time. One or more touch data structures referencing the same time can be added in a touch event data structure that can define the states of all touches a particular view is receiving at a moment in time (as noted above, some touch data structures may also reference touches that have ended and are no longer being received). Multiple touch event data structures can be sent to the software implementing a view as time passes, in order to provide the software with continuous information describing the touches that are happening in the view.

The ability to handle complex touch-based gestures, optionally including multi-touch gestures, can add complexity to the various software elements. In some cases, such additional complexity can be necessary to implement advanced and desirable interface features. For example, a game may require the ability to handle multiple simultaneous touches that occur in different views, as games often require the pressing of multiple buttons at the same time, or combining accelerometer data with touches on a touch-sensitive surface. However, some simpler applications and/or views (and their associated software elements) need not require advanced interface features. For example, a simple soft button (i.e., a button that is displayed on a touch-sensitive display) may operate satisfactorily with single touches, rather than multi-touch functionality. In these cases, the underlying OS may send unnecessary or excessive touch data (e.g., multi-touch data) to a software element associated with a view that is intended to be operable by single touches only (e.g., a single touch or tap on a soft button). Because the software element may need to process this data, it may need to feature all the complexity of a software element that handles multiple touches, even though it is associated with a view for which only single touches are relevant. This can increase the cost of development of software for the device, because software elements that have been traditionally easy to program in a mouse interface environment (i.e., various buttons, etc.) may be much more complex in a multi-touch environment.

It shall be understood, however, that the foregoing discussion regarding the complexity of evaluating and processing user touches on touch-sensitive surfaces also applies to all forms of user inputs to operate electronic devices 102 and 104 with input-devices, 128 and 158, respectively, not all of which are initiated on touch screens, e.g., coordinating mouse movement and mouse button presses with or without single or multiple keyboard presses or holds, user movements taps, drags, scrolls, etc., on touch-pads, pen stylus inputs, oral instructions, detected eye movements, biometric inputs, detected physiological change in a user, and/or any combination thereof, which may be utilized as inputs corresponding to sub-events which define an event to be recognized.

FIG. 4A depicts an event recognizer state machine 400 containing four states. By managing state transitions in event recognizer state machine 400 based on received sub-events, an event recognizer effectively expresses an event definition. For example, a tap gesture may be effectively defined by a sequence of two, or optionally, three sub-events. First, a touch should be detected, and this will be sub-event 1. For example, the touch sub-event may be a user's finger touching a touch-sensitive surface in a view that includes the event recognizer having state machine 400. Second, an optional measured delay where the touch does not substantially move in any given direction (e.g., any movement of the touch position is less than a predefined threshold, which may be measured as a distance (e.g., 5 mm) or as a number of pixels (e.g., 5 pixels) on the display), and the delay is sufficiently short, would serve as sub-event 2. Finally, termination of the touch (e.g., liftoff of the user's finger from the touch-sensitive surface) will serve as sub-event 3. By coding the event recognizer state machine 400 to transition between states based upon receiving these sub-events, the event recognizer state machine 400 effectively expresses a tap gesture event definition.

Regardless of event type, the event recognizer state machine 400 begins in an event recognition begins state 405, and may progress to any of the remaining states depending on what sub-event is received. To facilitate discussion of the event recognizer state machine 400, the direct paths from the event recognition begins state 405 to the event recognized state 415, the event possible state 410, and event impossible state 420 will be discussed, followed by a description of the paths leading from the event possible state 410.

Starting from event recognition begins state 405, if a sub-event is received that, by itself comprises the event definition for an event, the event recognizer state machine 400 will transition to event recognized state 415.

Starting from state event recognition begins 405, if a sub-event is received that is not the first sub-event in an event definition, the event recognizer state machine 400 will transition to event impossible state 420.

Starting from event recognition begins state 405, if a sub-event is received that is the first and not final sub-event in a given event definition, the event recognizer state machine 400 will transition to event possible state 410. If the next sub-event received is a second sub-event, but not the final sub-event in the given event definition, the event recognizer state machine 400 will remain in state event possible 410. The event recognizer state machine 400 can remain in state event possible 410 for as long as the sequence of received sub-events continues to be part of the event definition. If, at any time the event recognizer state machine 400 is in event possible state 410, and the event recognizer state machine 400 receives a sub-event that is not part of the event definition, it will transition to state event impossible 420, thereby determining that the current event (if any) is not the type of event that corresponds to this event recognizer (i.e., the event recognizer corresponding to state 400). If, on the other hand, the event recognizer state machine 400 is in the event possible state 410, and the event recognizer state machine 400 receives the last sub-event in an event definition, it will transition to the event recognized state 415, thereby completing a successful event recognition.

FIG. 4B depicts an embodiment of an input source handling process 440, having a finite state machine representing how views receive information about a respective input. It is noted that when there are multiple touches on the touch-sensitive surface of a device, each of the touches is a separate input source having its own finite state machine. In this embodiment, input source handling process 440 includes four states: input sequence begin 445, input sequence continues 450, input sequence ended 455, and input sequence cancelled 460. Input source handling process 440 may be used by a respective event recognizer, for example, when input is to be delivered to an application, but only after the completion of an input sequence is detected. Input source handling process 440 can be used with an application that is incapable of canceling or undoing changes made in response to an input sequence delivered to the application.

Starting from input sequence begin 445, if an input is received that, by itself completes an input sequence, input source handling process 440 will transition to input sequence ended 455.

Starting from input sequence begin 445, if an input is received that indicates the input sequence terminated, input source handling process 440 will transition to input sequence cancelled 460.

Starting from input sequence begin 445, if an input is received that is the first and not final input in a input sequence, input source handling process 440 will transition to state input sequence continues 450. If the next input received is the second input in an input sequence, the input handling process 440 will remain in state input sequence continues 450. Input source handling process 440 can remain in state input sequence continues 450 for as long as the sequence of sub-events being delivered continue to be part of a given input sequence. If, at any time input source handling process 440 is in state input sequence continues 450, and input source handling process 440 receives an input that is not part of the input sequence, it will transition to state input sequence cancelled 460. If, on the other hand, input source handling process 440 is in input sequence continues 450, and the input handling process 440 receives the last input in a given input definition, it will transition to the input sequence ended 455, thereby successfully receiving a group of sub-events.

In some embodiments, input source handling process 440 may be implemented for particular views or programmatic levels. In that case, certain sequences of sub-events may result in transitioning to state input cancelled 460.

As an example, consider FIG. 4C, which supposes an actively involved view, represented only by actively involved view input source handler 480 (hereafter “view 480”). View 480 includes a vertical swipe event recognizer, represented only by vertical swipe event recognizer 468 (hereafter “recognizer 468”) as one of its event recognizers. In this case, the recognizer 468 may require as part of its definition detecting: 1) a finger down 465-1; 2) an optional short delay 465-2; 3), vertical swiping of at least N pixels 465-3; and 4) a finger liftoff 465-4.

For this example, the recognizer 468 also has its delay touch began flag 328 and touch cancellation flag 332 set. Now consider delivery of the following sequence of sub-events to recognizer 468, as well as the view 480:

-   -   sub-event sequence 465-1: detect finger down, which corresponds         to recognizer 468's event definition     -   sub-event sequence 465-2: measure delay, which corresponds to         recognizer 468's event definition     -   sub-event sequence 465-3: finger performs a vertical swiping         movement compatible with vertical scrolling, but is less than N         pixels, and therefore does not correspond to recognizer 468's         event definition     -   sub-event sequence 465-4: detect finger liftoff, which         corresponds to recognizer 468's event definition

Here, recognizer 468 would successfully recognize sub-events 1 and 2 as part of its event definition, and accordingly, would be in state event possible 472 immediately prior to the delivery of sub-event 3. Since recognizer 468 has its delay touch began flag 328 set, the initial touch sub-event is not sent to the hit view. Correspondingly, the view 480's input source handling process 440 would still be in state input sequence begin immediately prior to the delivery of sub-event 3.

Once delivery of sub-event 3 to recognizer 468 is complete, recognizer 468's state transitions to event impossible 476, and importantly, the recognizer 468 has now determined that the sequence of sub-events does not correspond to its specific vertical swipe gesture event type (i.e., it has decided the event is not a vertical swipe. In other words, recognition 474 as a vertical swipe does not occur in this example.). The input source handling system 440 for view input source handler 480 will also update its state. In some embodiments, the state of the view input source handler 480 would proceed from the input sequence begins state 482 to the input sequence continues state 484 when the event recognizer sends status information indicating that it has begun recognizing an event. The view input source handler 480 proceeds to the input sequence cancelled state 488 when the touch or input ends without an event being recognized because the touch cancellation flag 322 of the event recognizer has been set. Alternately, if the touch cancellation flag 322 of the event recognizer had not been set, the view input source handler 480 proceeds to the input sequence ended state 486 when the touch of input ends.

Since event recognizer 468's touch cancellation flag 332 is set, when the event recognizer 468 transitions to the event impossible state 476, the recognizer will send a touch cancellation sub-event or message to the hit view corresponding to the event recognizer. As a result, the view input source handler 480 will transition to the state input sequence cancelled 488.

In some embodiments, delivery of sub-event 465-4 is not germane to any event recognition decisions made by recognizer 468, though view input source handler 480's other event recognizers, if any, may continue to analyze the sequence of sub-events.

The following table presents in summarized tabular format the processing of this exemplary sub-event sequence 465 as related to the state of event recognizer 468 described above, along with the state of view input source handler 480. In this example, the state of the view input source handler 480 proceeds from input sequence begin 445 to input sequence cancelled 488 because recognizer 468's touch cancellation flag 332 was set:

Sub-Event Sequence State: Recognizer 465 468 State: View 480 before delivery Event Recognition starts Begins 470 detect finger down Event Possible 472 Input Sequence 465-1 Begins 482 measure delay 465-2 Event Possible 472 Input Sequence Continues 484 detect finger vertical Event Impossible Input Sequence swipe 465-3 476 Continues 484 detect finger liftoff Event Impossible Input Sequence 465-4 476 Cancelled 488

Turning to FIG. 5A, attention is directed to an example of a sub-event sequence 520, which is being received by a view that includes a plurality of event recognizers. For this example, two event recognizers are depicted in FIG. 5A, scrolling event recognizer 580 and tap event recognizer 590. For purposes of illustration, the view search results panel 304 in FIG. 3A will be related to the reception of the sub-event sequence 520, and the state transitions in scrolling event recognizer 580 and tap event recognizer 590. Note that in this example, the sequence of sub-events 520 defines a tap finger gesture on a touch-sensitive display or trackpad, but the same event recognition technique could be applied in myriad contexts, e.g., detecting a mouse button press, and/or in embodiments utilizing programmatic hierarchies of programmatic levels.

Before the first sub-event is delivered to view search results panel 304, event recognizers 580 and 590 are in the event recognition begins states 582 and 592, respectively. Following touch 301, which is delivered as sub-event detect finger down 521-1 to actively involved event recognizers for view search results panel 304 as touch sub-event 301-2 (as well as to actively involved event recognizers for map view 305 as touch sub-event 301-3), scrolling event recognizer 580 transitions to state event possible 584, and similarly, tap event recognizer 590 transitions to state event possible 594. This is because the event definition of a tap and a scroll both begin with a touch such as detecting a finger down on a touch-sensitive surface.

Some definitions of tap and scroll gestures may optionally include a delay between an initial touch and any next step in the event definition. In all examples discussed here, the exemplar event definitions for both tap and scroll gestures recognize a delay sub-event following the first touch sub-event (detect finger down).

Accordingly, as sub-event measure delay 521-2 is delivered to event recognizers 580 and 590, both remain in the event possible states 584 and 594, respectively.

Finally, sub-event detect finger liftoff 521-3 is delivered to event recognizers 580 and 590. In this case, the state transitions for event recognizers 580 and 590 are different, because the event definitions for tap and scroll are different. In the case of scrolling event recognizer 580, the next sub-event to remain in state event possible would be to detect movement. Since the sub-event delivered is detect finger liftoff 521-3, however, the scrolling event recognizer 580 transitions to state event impossible 588. A tap event definition concludes with a finger liftoff sub-event though. Accordingly, tap event recognizer 590 transitions to state event recognized 596 after sub-event detect finger liftoff 521-3 is delivered.

Note that in some embodiments, as discussed above with respect to FIGS. 4B and 4C, the input source handling process 440 discussed in FIG. 4B may be used for various purposes at the view level. The following table presents in summarized tabular format the delivery of sub-event sequence 520 as related to event recognizers 580, 590, and input source handling process 440:

Sub-Event State: Scrolling State: Tap State: Input Sequence Event Recog- Event Recog- Source Handling 520 nizer 580 nizer 590 Process 440 before delivery Event Event starts Recognition Recognition Begins 582 Begins 592 Detect Finger Event Event Input Sequence Down 521-1 Possible 584 Possible 594 Begin 445 Measure Delay Event Event Input Sequence 521-2 Possible 584 Possible 594 Continues 450 Detect Finger Event Event Input Sequence Liftoff 521-3 impossible Recognized Ended 455 588 596

Turning to FIG. 5B, attention is directed to another example of a sub-event sequence 530, which is being received by a view that includes a plurality of event recognizers. For this example, two event recognizers are depicted in FIG. 5B, scrolling event recognizer 580 and tap event recognizer 590. For purposes of illustration, the view search results panel 304 in FIG. 3A will be related to the reception of the sub-event sequence 530, and the state transitions in scrolling event recognizer 580 and tap event recognizer 590. Note that in this example, the sequence of sub-events 530 defines a scroll finger gesture on a touch-sensitive display, but the same event recognition technique could be applied in myriad contexts, e.g., detecting a mouse button press, mouse movement, and mouse button release, and/or in embodiments utilizing programmatic hierarchies of programmatic levels.

Before the first sub-event is delivered to actively involved event recognizers for view search results panel 304, event recognizers 580 and 590 are in the event recognition begins states 582 and 592, respectively. Following delivery of sub-events corresponding to touch 301 (as discussed above), scrolling event recognizer 580 transitions to state event possible 584, and similarly, tap event recognizer 590 transitions to state event possible 594.

As sub-event measure delay 531-2 is delivered to event recognizers 580 and 590, both transition to the event possible states 584 and 594, respectively.

Next, sub-event detect finger movement 531-3 is delivered to event recognizers 580 and 590. In this case, the state transitions for event recognizers 580 and 590 are different because the event definitions for tap and scroll are different. In the case of scrolling event recognizer 580, the next sub-event to remain in state event possible is to detect movement, so the scrolling event recognizer 580 remains in the event possible state 584 when it receives sub-event detect finger movement 531-3. As discussed above, however, the definition for a tap concludes with a finger liftoff sub-event, so tap event recognizer 590 transitions to the state event impossible 598.

Finally, sub-event detect finger liftoff 531-4 is delivered to event recognizers 580 and 590. Tap event recognizer is already in the event impossible state 598, and no state transition occurs. Scrolling event recognizer 580's event definition concludes with detecting a finger liftoff. Since the sub-event delivered is detect finger liftoff 531-4, the scrolling event recognizer 580 transitions to state event recognized 586. It is noted that a finger movement on a touch sensitive surface may generate multiple movement sub-events, and therefore a scroll may be recognized before liftoff and continue until liftoff.

The following table presents in summarized tabular format the delivery of sub-event sequence 530 as related to event recognizers 580, 590, and input source handling process 440:

Sub-Event State: Scrolling State: Tap State: Input Sequence Event Recog- Event Recog- Source Handling 530 nizer 580 nizer 590 Process 440 before delivery Event Event starts Recognition Recognition Begins 582 Begins 592 detect finger Event Event Input Sequence down 531-1 Possible 584 Possible 594 Begins 445 measure delay Event Event Input sequence 531-2 Possible 584 Possible 594 continues 450 detect finger Event Event Input sequence movement 531-3 Possible 584 Impossible continues 450 598 detect finger Event Event Input sequence liftoff 531-4 Recognized Impossible ended 455 586 598

Turning to FIG. 5C, attention is directed to another example of a sub-event sequence 540, which is being received by a view that includes a plurality of event recognizers. For this example, two event recognizers are depicted in FIG. 5C, double tap event recognizer 570 and tap event recognizer 590. For purposes of illustration, the map view 305 in FIG. 3A will be related to the reception of the sub-event sequence 540, and the state transitions in double tap event recognizer 570 and tap event recognizer 590. Note that in this example, the sequence of sub-events 540 defines a double tap gesture on a touch-sensitive display, but the same event recognition technique could be applied in myriad contexts, e.g., detecting a mouse double click, and/or in embodiments utilizing programmatic hierarchies of programmatic levels.

Before the first sub-event is delivered to actively involved event recognizers for map view 305, event recognizers 570 and 590 are in the event recognition begins states 572 and 592, respectively. Following delivery of sub-events related to touch sub-event 301 to map view 304 (as described above), double tap event recognizer 570 and tap event recognizer 590 transition to states event possible 574 and 594, respectively. This is because the event definition of a tap and a double tap both begin with a touch such as detecting a finger down on a touch-sensitive surface.

As sub-event measure delay 541-2 is delivered to event recognizers 570 and 590, both remain in states event possible 574 and 594, respectively.

Next, sub-event detect finger liftoff 541-3 is delivered to event recognizers 570 and 590. In this case, the state transitions for event recognizers 580 and 590 are different because the exemplar event definitions for tap and double tap are different. In the case of tap event recognizer 590, the final sub-event in the event definition is to detect finger liftoff, so the tap event recognizer 590 transitions to the event recognized state 596.

Double tap recognizer 570 remains in state event possible 574, however, since a delay has begun, regardless of what the user may ultimately do. The complete event recognition definition for a double tap requires another delay, followed by a complete tap sub-event sequence though. This creates an ambiguous situation as between the tap event recognizer 590, which is already in state event recognized 576, and the double tap recognizer 570, which is still in state event possible 574.

Accordingly, in some embodiments, event recognizers may implement exclusivity flags and exclusivity exception lists as discussed above with respect to FIGS. 3B and 3C. Here, the exclusivity flag 324 for tap event recognizer 590 would be set, and additionally, exclusivity exception list 326 for tap event recognizer 590 would be configured to continue permitting delivery of sub-events to some event recognizers (such as double tap event recognizer 570) after tap event recognizer 590 enters the state event recognized 596.

While tap event recognizer 590 remains in state event recognized 596, sub-event sequence 540 continues to be delivered to double tap event recognizer 570, where sub-events measure delay 541-4, detect finger down 541-5, and measure delay 541-6, keep the double tap event recognizer 570 in the state event possible 574; delivery of the final sub-event of sequence 540, detect finger liftoff 541-7 transitions double tap event recognizer 570 to state event recognized 576.

At this point, the map view 305 takes the event double tap as recognized by event recognizer 570, rather than the single tap event recognized by tap event recognizer 590. The decision to take the double tap event is made in light of the combination of the tap event recognizer 590's exclusivity flag 324 being set, the tap event recognizer 590's exclusivity exception list 326 including a double tap event, and the fact that both the tap event recognizer 590 and the double tap event recognizer 570 both successfully recognized their respective event types.

The following table presents in summarized tabular format the delivery of sub-event sequence 540 as related to event recognizers 570 and 590, and sub-event handling process 440:

State: Double Sub-Event Tap Event State: Tap State: Input Sequence Recog- Event Recog- Source Handling 540 nizer 570 nizer 590 Process 440 before delivery Event Event starts Recognition Recognition Begins 572 Begins 592 detect finger Event Event Input Sequence down 541-1 Possible 574 Possible 594 Begins 445 measure delay Event Event Input sequence 541-2 Possible 574 Possible 594 continues 450 detect finger Event Event Input sequence liftoff 541-3 Possible 574 Recognized continues 450 596 measure delay Event Event Input sequence 541-4 Possible 574 Recognized continues 450 596 detect finger Event Event Input sequence down 541-5 Possible 574 Recognized continues 450 596 measure delay Event Event Input sequence 541-6 Possible 574 Recognized continues 450 596 detect finger Event Event Input sequence liftoff 541-7 Recognized Recognized ended 455 576 596

In another embodiment, in the event scenario of FIG. 5C, the single tap gesture is not recognized, because the single tap event recognizer has a wait-for list that identifies the double tap event recognizer. As a result, a single tap gesture is not recognized until (if ever) the double tap event recognizer enters the event impossible state. In this example, in which a double tap gesture is recognized, the single tap event recognizer would remain in the event possible state until the double tap gesture is recognized, at which point the single tap event recognizer would transition to the event impossible state.

Attention is now directed to FIGS. 6A and 6B, which are flow diagrams illustrating an event recognition method in accordance with some embodiments. The method 600 is performed at an electronic device, which in some embodiments, may be an electronic device 102 or 104, as discussed above. In some embodiments, the electronic device may include a touch sensitive surface configured to detect multi-touch gestures. Alternatively, the electronic device may include a touch screen configured to detect multi-touch gestures.

The method 600 is configured to execute software that includes a view hierarchy with a plurality of views. The method 600 displays 608 one or more views of the view hierarchy, and executes 610 one or more software elements. Each software element is associated with a particular view, and each particular view includes one or more event recognizers, such as those described in FIGS. 3B and 3C as event recognizer structures 320 and 360, respectively.

Each event recognizer generally includes an event definition based on one or more sub-events, where the event definition may be implemented as a state machine, see e.g., FIG. 3B state machine 340. Event recognizers also generally include an event handler, which specifies an action for a target, and is configured to send the action to the target in response to the event recognizer detecting an event corresponding to the event definition.

In some embodiments, at least one of the plurality of event recognizers is a gesture recognizer having a gesture definition and a gesture handler as noted in step 612 of FIG. 6A.

In some embodiments, the event definition defines a user gesture as noted in step 614 of FIG. 6A.

Alternatively, event recognizers have a set of event recognition states 616. These event recognition states may include at least an event possible state, an event impossible state, and an event recognized state.

In some embodiments, the event handler initiates preparation 618 of its corresponding action for delivery to the target if the event recognizer enters the event possible state. As discussed above with respect to FIG. 4A and the examples in FIGS. 5A-5C, the state machines implemented for each event recognizer generally include an initial state, e.g., state event recognition begins 405. Receiving a sub-event that forms the initial part of an event definition triggers a state change to the event possible state 410. Accordingly, in some embodiments, as an event recognizer transitions from the state event recognition begins 405 to the state event possible 410, the event recognizer's event handler may begin preparing its particular action to deliver to the event recognizer's target after an event is successfully recognized.

On the other hand, in some embodiments, the event handler may terminate preparation 620 of its corresponding action if the event recognizer enters the state event impossible 420. In some embodiments, terminating the corresponding action includes canceling any preparation of the event handler's corresponding action.

The example of FIG. 5B is informative for this embodiment since tap event recognizer 590 may have initiated preparation 618 of its action, but then, once the sub-event detect finger movement 531-3 is delivered to the tap event recognizer 590, the recognizer 590 will transition to the event impossible state 598, 578. At that point, tap event recognizer 590 may terminate preparation 620 of the action for which it had initiated preparation 618.

In some embodiments, the event handler completes preparation 622 of its corresponding action for delivery to the target if the event recognizer enters the event recognized state. The example of FIG. 5C illustrates this embodiment since a double tap is recognized by actively involved event recognizers for the map view 305, which in some implementations, would be the event bound to selecting and/or executing the search result depicted by map view 305. Here, after the double tap event recognizer 570 successfully recognizes the double tap event comprised of the sub-event sequence 540, map view 305's event handler completes preparation 622 of its action, namely, indicating that it has received an activation command.

In some embodiments, the event handler delivers 624 its corresponding action to the target associated with the event recognizer. Continuing with the example of FIG. 5C, the action prepared, i.e. the activation command of the map view 305, would be delivered to the specific target associated with the map view 305, which may be any suitable programmatic method or object.

Alternatively, the plurality of event recognizers may independently process 626 the sequence of one or more sub-events in parallel.

In some embodiments, one or more event recognizers may be configured as exclusive event recognizers 628, as discussed above with respect to FIGS. 3B and 3C's exclusivity flags 324 and 364, respectively. When an event recognizer is configured as an exclusive event recognizer, the event delivery system prevents any other event recognizers for actively involved views (except those listed in the exception list 326, 366 of the event recognizer that recognizes the event) in the view hierarchy from receiving subsequent sub-events (of the same sequence of sub-events) after the exclusive event recognizer recognizes an event. Furthermore, when a non-exclusive event recognizer recognizes an event, the event delivery system prevents any exclusive event recognizers for actively involved views in the view hierarchy from receiving subsequent sub-events, except for those (if any) listed in the exception list 326, 366 of the event recognizer that recognizes the event.

In some embodiments, exclusive event recognizers may include 630 an event exception list, as discussed above with respect to FIGS. 3B and 3C's exclusivity exception lists 326 and 366, respectively. As noted in the discussion of FIG. 5C above, an event recognizer's exclusivity exception list can be used to permit event recognizers to continue with event recognition even when the sequence of sub-events making up their respective event definitions overlap. Accordingly, in some embodiments, the event exception list includes events whose corresponding event definitions have repetitive sub-events 632, such as the single tap/double tap event example of FIG. 5C.

Alternately, the event definition may define a user input operation 634.

In some embodiments, one or more event recognizers may be adapted to delay delivering every sub-event of the sequence of sub-events until after the event is recognized.

The method 600 detects 636 a sequence of one or more sub-events, and in some embodiments, the sequence of one or more sub-events may include primitive touch events 638. Primitive touch events may include, without limitation, basic components of a touch-based gesture on a touch-sensitive surface, such as data related to an initial finger or stylus touch down, data related to initiation of multi-finger or stylus movement across a touch-sensitive surface, dual finger movements in opposing directions, stylus lift off from a touch-sensitive surface, etc.

Sub-events in the sequence of one or more sub-events can include many forms, including without limitation, key presses, key press holds, key press releases, button presses, button press holds, button press releases, joystick movements, mouse movements, mouse button presses, mouse button releases, pen stylus touches, pen stylus movements, pen stylus releases, oral instructions, detected eye movements, biometric inputs, and detected physiological changes in a user, among others.

The method 600 identifies 640 one of the views of the view hierarchy as a hit view. The hit view establishes which views in the view hierarchy are actively involved views. An example is depicted in FIG. 3A, where the actively involved views 306 include search results panel 304, and maps view 305 because touch sub-event 301 contacted the area associated with the maps view 305.

In some embodiments, a first actively involved view within the view hierarchy may be configured 642 to prevent delivery of the respective sub-event to event recognizers associated with that first actively involved view. This behavior can implement the skip property discussed above with respect to FIGS. 3B and 3C (330 and 370, respectively). When the skip property is set for an event recognizer, delivery of the respective sub-event is still performed for event recognizers associated with other actively involved views in the view hierarchy.

Alternately, a first actively involved view within the view hierarchy may be configured 644 to prevent delivery of the respective sub-event to event recognizers associated with that first actively involved view unless the first actively involved view is the hit view. This behavior can implement the conditional skip property discussed above with respect to FIGS. 3B and 3C (332 and 372, respectively).

In some embodiments, a second actively involved view within the view hierarchy is configured 646 to prevent delivery of the respective sub-event to event recognizers associated with the second actively involved view and to event recognizers associated with ancestors of the second actively involved view. This behavior can implement the stop property discussed above with respect to FIGS. 3B and 3C (328 and 368, respectively).

The method 600 delivers 648 a respective sub-event to event recognizers for each actively involved view within the view hierarchy. In some embodiments, event recognizers for actively involved views in the view hierarchy process the respective sub-event prior to processing a next sub-event in the sequence of sub-events. Alternately, event recognizers for the actively involved views in the view hierarchy make their sub-event recognition decisions while processing the respective sub-event.

In some embodiments, event recognizers for actively involved views in the view hierarchy may process the sequence of one or more sub-events concurrently 650; alternatively, event recognizers for actively involved views in the view hierarchy may process the sequence of one or more sub-events in parallel.

In some embodiments, one or more event recognizers may be adapted to delay delivering 652 one or more sub-events of the sequence of sub-events until after the event recognizer recognizes the event. This behavior reflects a delayed event. For example, consider a single tap gesture in a view for which multiple tap gestures are possible. In that case, a tap event becomes a “tap+delay” recognizer. In essence, when an event recognizer implements this behavior, the event recognizer will delay event recognition until it is certain that the sequence of sub-events does in fact correspond to its event definition. This behavior may be appropriate when a recipient view is incapable of appropriately responding to cancelled events. In some embodiments, an event recognizer will delay updating its event recognition status to its respective actively involved view until the event recognizer is certain that the sequence of sub-events does not correspond to its event definition. As discussed above with respect to FIGS. 3B and 3C, delay touch began flag 328, 368, delay touch end flag 330, 370, and touch cancellation flag 332, 372 are provided to tailor sub-event delivery techniques, as well as event recognizer and view status information updates to specific needs.

The foregoing description, for purpose of explanation, has been described with reference to specific embodiments. However, the illustrative discussions above are not intended to be exhaustive or to limit the invention to the precise forms disclosed. Many modifications and variations are possible in view of the above teachings. The embodiments were chosen and described in order to best explain the principles of the invention and its practical applications, to thereby enable others skilled in the art to best utilize the invention and various embodiments with various modifications as are suited to the particular use contemplated. 

1. A method, comprising: at an electronic device configured to execute software that includes a view hierarchy with a plurality of views: displaying one or more views of the view hierarchy; executing one or more software elements, each software element being associated with a particular view that includes one or more event recognizers; detecting a sequence of one or more sub-events; identifying one of the views of the view hierarchy as a hit view, wherein the hit view establishes which views in the view hierarchy are actively involved views; and delivering a respective sub-event to event recognizers for multiple actively involved views within the view hierarchy, wherein each event recognizer for the multiple actively involved views in the view hierarchy processes the respective sub-event prior to processing a next sub-event in the sequence of sub-events.
 2. The method of claim 1, wherein each event recognizer for actively involved views in the view hierarchy processes the sequence of one or more sub-events concurrently.
 3. The method of claim 1, wherein a first actively involved view within the view hierarchy is configured to prevent delivery of the respective sub-event to one or more event recognizers associated with the first actively involved view.
 4. The method of claim 1, wherein a first actively involved view within the view hierarchy is configured to prevent delivery of the respective sub-event to one or more event recognizers associated with the first actively involved view unless the first actively involved view is the hit view.
 5. The method of claim 1, wherein a first actively involved view within the view hierarchy is configured to prevent delivery of the respective sub-event to one or more event recognizers associated with the first actively involved view and to one or more event recognizers associated with one or more ancestors of the first actively involved view.
 6. The method of claim 1, wherein, for the particular view, at least one of the one or more event recognizers is a gesture recognizer having a gesture definition and a gesture handler.
 7. The method of claim 1, wherein the electronic device further comprises a touch sensitive surface configured to detect multi-touch gestures.
 8. The method of claim 1, wherein the electronic device further comprises a touch screen configured to detect multi-touch gestures.
 9. The method of claim 1, wherein the sequence of one or more sub-events includes primitive touch events.
 10. The method of claim 1, wherein each event recognizer has a set of event recognition states including at least an event possible state, an event impossible state, and an event recognized state.
 11. The method of claim 10, wherein a respective event handler is configured to initiate preparation of a corresponding action for delivery to a respective target if the respective event recognizer enters the event possible state.
 12. The method of claim 11, wherein the respective event handler is configured to complete preparation of the corresponding action for delivery to the respective target if the respective event recognizer enters the event recognized state.
 13. The method of claim 12, wherein the event handler is configured to deliver the corresponding action to the respective target.
 14. The method of claim 1, wherein, for the multiple actively involved views, the event recognizers independently process the sequence of one or more sub-events in parallel.
 15. The method of claim 1, wherein at least one event recognizer of the one or more event recognizers is adapted to delay delivering one or more sub-events of the sequence of sub-events until after the event is recognized.
 16. The method of claim 1, wherein, one or more exclusive event recognizers, comprising a subset of the event recognizers for the multiple actively involved views, are configured to perform exclusive event recognition, and the method further comprises: when any of the one or more exclusive event recognizers recognizes an event, preventing any other event recognizers for the multiple actively involved views in the view hierarchy from receiving subsequent sub-events of the sequence of sub-events.
 17. The method of claim 16, wherein the one or more exclusive event recognizers include an event exception list.
 18. The method of claim 17, wherein the event exception list includes events whose corresponding event definitions have repetitive sub-events.
 19. The method of claim 1, wherein the event definition defines a user input operation.
 20. The method of claim 1, wherein the respective sub-event of the sequence of one or more sub-events is selected from the group consisting of a key press, a key press hold, a key press release, a button press, a button press hold, a button press release, a joystick movement, a mouse movement, a mouse button press, a mouse button release, a pen stylus touch, a pen stylus movement, a pen stylus release, an oral instruction, a detected eye movement, a biometric input, and a detected physiological change in a user.
 21. A method, comprising: at an electronic device configured to execute software that includes a view hierarchy with a plurality of views: displaying one or more views of the view hierarchy; executing one or more software elements, each software element being associated with a particular view, wherein each particular view includes one or more event recognizers; detecting a sequence of one or more sub-events; identifying one of the views of the view hierarchy as a hit view, wherein the hit view establishes which views in the view hierarchy are actively involved views; delivering a respective sub-event to event recognizers for multiple actively involved views within the view hierarchy; and at event recognizers for the multiple actively involved views in the view hierarchy, making a sub-event recognition decision while processing the respective sub-event.
 22. The method of claim 21, wherein each event recognizer for actively involved views in the view hierarchy processes the sequence of one or more sub-events in parallel.
 23. A non-transitory computer readable storage medium storing one or more programs for execution by one of more processors of a computer system or device, the one or more programs including: one or more application programs for displaying one or more views of a view hierarchy with a plurality of views, the one or more application programs including one or more software elements, each software element being associated with a particular view that includes one or more event recognizers; and event management instructions, which when executed by the one or more processors of the computer system or device, cause the computer system or device to: detect a sequence of one or more sub-events; identify one of the views of the view hierarchy as a hit view, wherein the hit view establishes which views in the view hierarchy are actively involved views; and deliver a respective sub-event to event recognizers for multiple actively involved view within the view hierarchy, wherein each event recognizer for the multiple actively involved views in the view hierarchy processes the respective sub-event prior to processing a next sub-event in the sequence of sub-events.
 24. An apparatus, comprising: a display; one or more processors; and memory storing: one or more programs for displaying one or more views of a view hierarchy with a plurality of views, the one or more programs including one or more software elements, each software element being associated with a particular view that includes one or more event recognizers; and an event delivery program, which, when executed by the one or more processors of the apparatus, causes the apparatus to: detect a sequence of one or more sub-events; identify one of the views of the view hierarchy as a hit view, wherein the hit view establishes which views in the view hierarchy are actively involved views; deliver a respective sub-event to event recognizers for multiple actively involved view within the view hierarchy; and make a sub-event recognition decision while event recognizers for the multiple actively involved views in the view hierarchy process the respective sub-event.
 25. The non-transitory computer readable storage medium of claim 23, wherein each event recognizer for the multiple actively involved views in the view hierarchy is configured to process the sequence of one or more sub-events in parallel.
 26. The apparatus of claim 24, wherein each event recognizer for the multiple actively involved views in the view hierarchy is configured to process the sequence of one or more sub-events in parallel.
 27. An electronic device, comprising: a display; one or more processors; and memory storing one or more programs for execution by the one or more processors, the one or more programs including instructions for: displaying one or more views of a view hierarchy with a plurality of views; executing one or more software elements, each software element being associated with a particular view that includes one or more event recognizers; detecting a sequence of one or more sub-events; identifying one of the views of the view hierarchy as a hit view, wherein the hit view establishes which views in the view hierarchy are actively involved views; and delivering a respective sub-event to event recognizers for multiple actively involved views within the view hierarchy, wherein each event recognizer for the multiple actively involved views in the view hierarchy processes the respective sub-event prior to processing a next sub-event in the sequence of sub-events.
 28. The electronic device of claim 27, wherein each event recognizer for the multiple actively involved views in the view hierarchy is configured to process the sequence of one or more sub-events concurrently.
 29. A non-transitory computer readable storage medium storing one or more programs for execution by one of more processors of a computer system or device, the one or more programs including instructions for: displaying one or more views of a view hierarchy with a plurality of views; executing one or more software elements, each software element being associated with a particular view that includes one or more event recognizers; detecting a sequence of one or more sub-events; identifying one of the views of the view hierarchy as a hit view, wherein the hit view establishes which views in the view hierarchy are actively involved views; and delivering a respective sub-event to event recognizers for multiple actively involved views within the view hierarchy, wherein each event recognizer for the multiple actively involved views in the view hierarchy processes the respective sub-event prior to processing a next sub-event in the sequence of sub-events.
 30. The non-transitory computer readable storage medium of claim 29, wherein each event recognizer for the multiple actively involved views in the view hierarchy is configured to process the sequence of one or more sub-events concurrently. 